麻醉猫中呼吸神经元的腺苷能调节及低氧反应
Adenosinergic modulation of respiratory neurones and hypoxic responses in the anaesthetized cat.
作者信息
Schmidt C, Bellingham M C, Richter D W
机构信息
II Department of Physiology, University of Göttingen, Germany.
出版信息
J Physiol. 1995 Mar 15;483 ( Pt 3)(Pt 3):769-81. doi: 10.1113/jphysiol.1995.sp020621.
Abstract
- The modulatory effects of intracellularly injected adenosine on membrane potential, input resistance and spontaneous or evoked synaptic activity were determined in respiratory neurones of the ventral respiratory group. 2. The membrane potential hyperpolarized and sometimes reached values which were beyond the equilibrium potential of Cl(-)-dependent IPSPs. At the same time, neuronal input resistance decreased. 3. Spontaneous and stimulus-evoked postsynaptic activities were decreased, as were mean respiratory drive potentials. 4. Systemic injection of the A1 adenosine receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX; 0.01-0.05 mg kg-1) resulted in an increase in mean peak phrenic nerve activity when arterial chemoreceptors were denervated. In contrast, phrenic nerve activity decreased when arterial chemoreceptors were left intact. 5. The depressant effect of adenosine on synaptic activity was abolished after systemic DPCPX administration. DPCPX caused an increase in respiratory drive potentials, increased the amplitude of stimulus-evoked IPSPs, and hyperpolarized membrane potential. 6. Administration of DPCPX blocked the early hypoxic depression of stimulus-evoked IPSPs, doubled the delay of onset of hypoxic apnoea and shortened the time necessary for recovery of the respiratory rhythm. 7. The data indicate that adenosine acts on pre- and postsynaptic A1 receptors resulting in postsynaptic membrane hyperpolarization and depression of synaptic transmission. Blockade of A1 receptors increases respiratory activity, indicating that adenosine A1 receptors are tonically activated under control conditions. Further activation contributes to the hypoxic depression of synaptic transmission in the respiratory network.
摘要
- 在腹侧呼吸组的呼吸神经元中,测定了细胞内注射腺苷对膜电位、输入电阻以及自发或诱发突触活动的调节作用。2. 膜电位超极化,有时达到超过氯离子依赖性抑制性突触后电位(IPSPs)平衡电位的值。与此同时,神经元输入电阻降低。3. 自发和刺激诱发的突触后活动减少,平均呼吸驱动电位也减少。4. 全身注射A1腺苷受体拮抗剂8-环戊基-1,3-二丙基黄嘌呤(DPCPX;0.01 - 0.05毫克/千克),在切断动脉化学感受器神经支配时,导致膈神经平均峰值活动增加。相反,当动脉化学感受器保持完整时,膈神经活动减少。5. 全身给予DPCPX后,腺苷对突触活动的抑制作用被消除。DPCPX导致呼吸驱动电位增加,刺激诱发的IPSPs幅度增加,膜电位超极化。6. 给予DPCPX可阻断刺激诱发的IPSPs的早期低氧抑制,使低氧性呼吸暂停的起始延迟加倍,并缩短呼吸节律恢复所需的时间。7. 数据表明,腺苷作用于突触前和突触后A1受体,导致突触后膜超极化和突触传递抑制。阻断A1受体可增加呼吸活动,表明在对照条件下腺苷A1受体处于紧张性激活状态。进一步激活会导致呼吸网络中突触传递的低氧抑制。
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